Application of automatic image analysis for morphometric studies of peroxisomes stained cytochemically for catalase

Summary The feasibility of the application of an electronic image analyzer, the Texture Analysis System (TAS) (Leitz Wetzlar, FRG), for fast automatic ultrastructural morphometric studies of hepatic peroxisomes has been investigated. Rat liver peroxisomes were stained selectively with the alkaline DAB procedure for localization of catalase in order to obtain sufficient contrast for automatic detection by TAS. Electron micrographs of ultrathin sections from this material were analyzed both automatically by TAS and manually by using a digitizer tablet connected with an Apple IIe microcomputer. The results showed negligible differences. As far as the speed of the operation is concerned, the image analysis was 4–5 times faster than the manual technique. In further studies, the importance of using DAB-stained sections for accurate morphometric studies of peroxisomes was demonstrated by comparing the results of such DAB-stained preparations with unstained material. This revealed that the numerical density was lower and the average profile diameter higher in unstained sections. The value for volume density was also affected, being about 30% lower in such preparations. It is likely that in unstained preparations small peroxisomes without crystalline nucleoids were frequently not identified as such and were not taken into account in morphometric calculations.These observations establish that computer-controlled electronic image analysis in conjunction with selective cytochemical staining of peroxisomes for catalase provides a fast, accurate and reliable method for ultrastructural morphometric studies of this organelle in rat liver.     

Light microscopic morphometric analysis of peroxisomes by automatic image analysis: advantages of immunostaining over the alkaline DAB method.

The feasibility of light microscopic post-embedding immunocytochemistry for morphometry of peroxisomes using automatic image analysis was investigated and compared with the classical alkaline DAB method. Perfusion-fixed rat liver tissue was either embedded in LR White or incubated in the alkaline diaminobenzidine (DAB) medium for cytochemical visualization of catalase. Sections from the LR White-embedded material were incubated with a monospecific antibody against catalase, followed by protein A-gold and silver intensification. Determination of peroxisomal volume density in sections of different thickness revealed that the values increased with section thickness in DAB-stained sections but were unaffected in immunostained preparations. Moreover, the absolute value for volume density of peroxisomes, as determined by light microscopy in immunostained sections, was quite close to the value obtained by analysis of electron microscopic preparations. Finally, morphometric analysis of bezafibrate-induced peroxisome proliferation revealed that the ratio of proliferation obtained by light microscopy in immunostained sections was very close to the results obtained by electron microscopic morphometry. The main advantage of post-embedding immunostaining for light microscopic morphometry is that it restricts the immunocytochemical reaction product to the surface of the section, thus making it independent of section thickness.     

Automatic determination of labeling density in protein A-gold immunocytochemical preparations using an image analyzer. Application to peroxisomal enzymes

The application of an automatic image analyzer (TAS, Leitz, Wetzlar) for determination of labeling density in protein A-gold labeled sections is described. Electron micrographs of rat liver labeled with 12 nm gold particles for peroxisomal enzymes are placed on the macrounit of TAS and the images of peroxisomes on TAS-monitor are contoured with a light pen. The instrument measures the surface of the contoured areas. Based on their gray level, the gold particles over the peroxisome are detected automatically and counted and the labeling density for each peroxisome is calculated.     

Quantitative immunocytochemical studies on differential induction of serine

Summary Differential induction of serine: pyruvate aminotransferase (SPT) in rat liver parenchymal cells by administration of glucagon or di-(2-ethylhexyl)phthalate (DEHP) was studied using post-embedding immunocytochemical techniques and morphometric methods. Two groups of rats were fasted for 5 days and daily received peritoneal injection of glucagon (300 g/100 g) or physiological saline. Another two groups of rats were fed on laboratory chow with or without 2% DEHP for 2 weeks. Livers were perfusionfixed, cut into tissue sections (50–100 ), and processed to cytochemistry for catalase, immunocytochemistry for SPT, and conventional procedures for electron microscopy. The morphometric analysis showed that glucagon injection has negligible effect on the volume and numerical density and mean diameter of peroxisomes, whereas volume density of mitochondria was decreased by 25%. By DEHP administration peroxisomes were about 3-fold increased in the volume and numerical density. Mitochondria was increased about 40% in the numerical density, but unchanged in the volume density. Light and electron microscopic immunocytochemistry demonstrated that glucagon injection exclusively enhanced mitochondrial SPT, whereas DEHP administration exclusively induced in peroxisomal SPT. Quantitative analysis showed that by the glucagon injection, the labeling density of mitochondria was increased about 4-fold, but that of peroxisomes was 1.6 times as much as control, while by DEHP administration, the labeling density of peroxisomes was enhanced about 3-fold but that of mitochondria was decreased by 13%. The results clearly indicate that glucagon induces mitochondrial SPT, whereas peroxisome proliferator, DEHP induces peroxisomal SPT.     

Morphometric cytochemistry of diminution of catalase-containing peroxisomes in copper-loaded liver

Summary The density of hepatocellular catalase-containing peroxisomes was quantified, utilizing a computer-aided image analysing technique, on 1-m thick diaminobenzidine-stained sections. Hepatic copper accumulation following intraperitoneal injection of cupric chloride resulted in a dose-dependent reduction in the density of catalase-containing peroxisomes. A significant correlation between the density of peroxisomes and the activity of hepatic catalase indicated that computer-aided image analysis of peroxisomes stained by the diaminobenzidine technique provided a useful estimate of catalase activity in liver injured by copper. Slight treatment-related differences in the mean diameter of peroxisomes were detected in high-dose but not low-dose rats.     

Light microscopic identification and photography of Golgi impregnated central nervous system neurons during sectioning for electron microscopy.

A method is described for a rapid and systematic light microscopic documentation of Golgi impregnated neurons while they are being sectioned for electron microscopy. A drawing under the light microscope of a Golgi impregnated neuron is made first; subsequently thin sections of the tissue containing this neuron are cut in the same plane as for light microscopy. During thin sectioning the chuck containing the block is taken out of the ultramicrotome at regular intervals and placed in a special device under a light microscope. The neuron is photographed to record the stage of sectioning. Comparison of the micrographs indicates which part of the neuron and its dendritic tree are contained in the thin sections. No semithin sections are used and therefore no material is lost for reconstruction.     

Specific cytochemical stains in the image analysis of subcellular organelles

This paper describes our work concerning densitometry and morphometry of subcellular structures in thin sections. The techniques of automatic image analysis were applied to light and electron microscopic observations of enzymatically stained lysosomes, renal brush borders and mitochondria (in human and rat kidney) and peroxisomes (in human liver). To obtain significant measurements of the enzymatic activity, specific staining techniques were developed and applied, including an improved staining of acid phosphatase for lysosomes. Optical densities were obtained by videodensitometry and electron densities of peroxisomes were obtained by digitizing and processing scanning transmission electron microscopic images. In subsequent steps, delineations and parameter estimation are performed by software. Included was an examination of delineation techniques, which showed improved results from the use of a newly developed local boundary search algorithm. The combination of these techniques was used to study changes in peroxisome and lysosome compartment in liver and kidney, some results of which are also reported.     

The relationship between ram sperm head morphometry and fertility depends on the procedures of acquisition and analysis used

Sperm head morphometry is a parameter in the evaluation of semen that has been associated with fertility in two ways: comparing morphometric measures between predefined groups of fertility; or analyzing morphometric data by multivariate techniques to identify cell populations. We analyzed the morphometry of ram sperm head by three procedures and checked its relationship with male fertility. A Computer-Aided Sperm Morphometric Assessment procedure (CASMA), an image analysis software (NIS-Elements) in combination with an optical microscope (MO-NIS) and this image analysis software in combination with a scanning electron microscope (SEM-NIS) were used. Eight morphometric parameters were assessed: length, width, area, perimeter, ellipticity, form factor, elongation and regularity. We observed significant differences between the morphometric data of sperm head obtained with three study procedures. The CASMA procedure shows the highest values for all parameters and the SEM-NIS procedure the lowest. The analysis of a semen sample, when only the mean of morphometric parameters is used to describe the cell population, is too limited to interpret their fertilizing capacity. It is essential to analyze the complex structure of the samples by defining subpopulations by multivariate methods. With few exceptions, the means of each morphometric parameter differ between the three subpopulations analyzed in each procedure. Only the subpopulations obtained with the MO-NIS procedure showed a significant correlation with male fertility. In short, it is necessary to establish an instrumental standard for the analysis of sperm morphometry to obtain reliable results and we believe that the MO-NIS system presents these basic requirements.     

Light Microscopic Identification and Photography of Golgi Impregnated Central Nervous System Neurons During Sectioning for Electron Microscopy

A method is described for a rapid and systematic light microscopic documentation of Golgi impregnated neurons while they are being sectioned for electron microscopy. A drawing under the light microscope of a Golgi impregnated neuron is made first; subsequently thin door of the tissue containing this neuron are cut in the same plane as for light microscopy. During thin sectioning the chuck containing the block is taken out of the ultramicrotome at regular intervals and placed in a special device under a light microscope. The neuron is photographed to record the stage of sectioning. Comparison of the micrographs indicates which put of the and its dendritic tree are contained in the thin sections. No semithin sections are used and therefore no material is lost for reconstruction.     

Quantitative immunocytochemical studies on differential induction of serine:pyruvate aminotransferase in mitochondria and peroxisomes of rat liver cells by administration of glucagon or di-(2-ethylhexyl)phthalate

Differential induction of serine: pyruvate amino-transferase (SPT) in rat liver parenchymal cells by administration of glucagon or di-(2-ethylhexyl)phthalate (DEHP) was studied using post-embedding immunocytochemical techniques and morphometric methods. Two groups of rats were fasted for 5 days and daily received peritoneal injection of glucagon (300 micrograms/100 g) or physiological saline. Another two groups of rats were fed on laboratory chow with or without 2% DEHP for 2 weeks. Livers were perfusion-fixed, cut into tissue sections (50-100 micron), and processed to cytochemistry for catalase, immunocytochemistry for SPT, and conventional procedures for electron microscopy. The morphometric analysis showed that glucagon injection has negligible effect on the volume and numerical density and mean diameter of peroxisomes, whereas volume density of mitochondria was decreased by 25%. By DEHP administration peroxisomes were about 3-fold increased in the volume and numerical density. Mitochondria was increased about 40% in the numerical density, but unchanged in the volume density. Light and electron microscopic immunocytochemistry demonstrated that glucagon injection exclusively enhanced mitochondrial SPT, whereas DEHP administration exclusively induced in peroxisomal SPT. Quantitative analysis showed that by the glucagon injection, the labeling density of mitochondria was increased about 4-fold, but that of peroxisomes was 1.6 times as much as control, while by DEHP administration, the labeling density of peroxisomes was enhanced about 3-fold but that of mitochondria was decreased by 13%. The results clearly indicate that glucagon induces mitochondrial SPT, whereas peroxisome proliferator, DEHP induces peroxisomal SPT.     

Peroxisomes in guinea pig liver: their peculiar morphological features may reflect certain aspects of lipoprotein metabolism in this species

Summary We have studied the ultrastructural characteristics and the distribution of peroxisomes in guinea pig liver using electron-microscopic cytochemistry for catalase and morphometry. By light microscopy, peroxisomes appear as dark 0.2–0.5 m granules in the cytoplasm of liver parenchymal cells, often forming large clusters that measure up to 5 m across. Rows of single peroxisomes or their aggregates line the sinusoidal surface of hepatocytes. Electron microscopy reveals that clusters of up to 25 individual peroxisomes are usually located in the subsinusoidal region of parenchymal cells. The mean diameter and the volume density of peroxisomes are larger in pericentral than in periportal regions of the liver lobule. Whereas large amounts of lipoprotein particles with a mean diameter of 160 nm (chylomicrons) are present in the Disse space, the cytoplasm of parenchymal cells contains multivesicular bodies and abundant lipid droplets. In addition, the Golgi complexes show distended lipoprotein-filled vesicles suggesting active biosynthesis of lipoproteins. We propose that the unique features of peroxisomes in guinea pig liver, such as cluster formation and alignment along the sinusoidal surface, may be related to the high levels of lipoproteins in the portal circulation and their hepatic catabolism in this species.     

Identification of etioplast membranes in fractions from soybean hypocotyls

Three independent methods, one cytological and two biochemical, were used to estimate contributions of plastids and plastid fragments to various membrane fractions. In thin sections viewed by electron microscopy, KMnO₄ selectively enhanced the images of plastid membranes in situ as well as in isolated fractions. The amounts of plastid fragments in isolated membrane fractions were determined by electron microscopic morphometry of fractions fixed with KMnO₄ in conjunction with analysis of galactolipids and carotenoids. Monogalactosyl and digalactosyl diglyceride contents were directly correlated with the amount of plastid membranes in the fractions identified by electron microscope morphometry. Amounts of carotenoids also correlated with plastid membranes except at very low levels where estimates based on carotenoids exceeded those based on morphometry.     

Detection of peroxisomes in human liver and kidney fixed with formalin and embedded in paraffin: the use of catalase and lipid beta-oxidation enzymes as immunocytochemical markers

Summary We describe the immunocytochemical localization of four peroxisomal enzymes by light microscopy in human liver and kidney processed routinely by formalin fixation and paraffin embedding. Monospecific antisera against catalase and three enzymes of peroxisomal lipid -oxidation (acyl-CoA oxidase, bifunctional protein (enoyl-CoA hydratase, 3-hydroxyacyl-CoA dehydrogenase) and 3-ketoacyl-CoA thiolase) were used in conjunction with either the indirect immunoperoxidase method or the protein A—gold technique followed by silver intensification. The sections of formalin-fixed paraffin-embedded tissue had to be deparaffinized and subjected to controlled proteolysis in order to obtain satisfactory immunostaining. Under the conditions employed, peroxisomes were distinctly visualized in liver parenchymal cells with no reaction in bile duct epithelial or sinusoidal lining cells. In the kidney, peroxisomes were confined to the proximal tubular epithelial cells with negative staining of glomeruli, distal tubules and collecting ducts. A positive immunocytochemical reaction was obtained even in paraffin blocks stored for several years. The method offers a simple approach for detection of peroxisomes and evaluation of their various enzyme proteins in material processed routinely in histopathology laboratories and should prove useful in the investigation of the role of peroxisomes in human pathology for both prospective and retrospective studies.     

Unconventional application of standard light and electron immunocytochemical analysis to aldehyde-fixed, araldite-embedded tissues

A simple procedure for the immunocytochemical analysis of glutaraldehyde/formaldehyde-fixed, Araldite- or Epon-embedded tissues by either light or electron microscopy is presented. Retention of immunoreactive antigen in deplasticized sections was achieved by use of a low concentration of glutaraldehyde in the fixative in combination with a seldom-used plastic solvent. This protocol produced good ultrastructural preservation in tissues and large, high-quality, 2-micrometers thick, plastic-free sections. These semithin sections provided a level of structural and antigenic preservation, image resolution, and labeling intensity that surpassed all other conventional sectioning methods used for immunocytochemistry. The capacity to use a single tissue sample in studies designed for light and electron immunocytochemistry, in conjunction with existing autoradiographic and cytochemical techniques, makes this a very desirable method for routine tissue preparation in research and clinical applications.     

Light and electron microscopic localization of L-alpha-hydroxyacid oxidase in rat kidney revealed by immunocytochemical techniques

Light and electron microscopic localization of L-alpha-hydroxyacid oxidase (L-HOX) in rat kidney was studied by means of immunocytochemical techniques. Isozymes A and B of L-HOX were purified from rat liver and kidney, respectively. The apparent molecular weights of the subunits of the isozymes A and B were 35,800 and 33,500 daltons, respectively, by a slab gel electrophoresis. Antibodies to the isozymes were raised in rabbits. Anti(isozyme A) is not cross-reactive with the isozyme B and vice versa anti(isozyme B) not with the isozyme A. Using anti-isozyme B, semithin sections of Epon-embedded material and ultrathin sections of Lowicryl K4M-embedded material were stained by immunoenzyme and protein A-gold techniques, respectively. By light microscopy, fine discrete granular staining was noted in proximal tubules, but not in distal tubules including thick and thin limbs of Henle and collecting tubules. By electron microscopy, gold particles representing the antigen sites for L-HOX B were confined exclusively to peroxisomes, in which most of the gold particles were localized in electron dense peripheral matrix, but little in central matrix with low electron density. The results indicate that L-HOX B does not homogeneously distribute in peroxisomes of rat kidney but might be associated with some substructure within peroxisome matrix.     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraf?n sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

Histochemical and immunohistochemical protocols for routine biopsies embedded in Lowicryl resin.

Tissue processing and analysis require good preservation of both the shape and content of cells. Lowicryl resin is one of the few embedding media that allow good preservation of both tissue architecture and cellular contents. Therefore, different histochemical and immunohistochemical reactions can be applied to semithin sister sections from one biopsy. Further examination of a zone of interest can be carried out under the electron microscope. The hydrophilic property of Lowicryl resins makes possible different histochemical reactions; however, the technique used for paraffin sections must be adapted for each reaction. Antigenic preservation of cells by low temperature embedding allows immunolabeling on either semithin sections or in the zone of interest on ultrathin sections. We have shown the application and adaptation of different histochemical and immunohistochemical reactions on semithin and ultrathin sections from hepatic biopsies that were large, but thin. The variety of techniques that can be used on sister Lowicryl sections of a single biopsy makes this medium useful for extensive pathological studies of precious needle biopsies.     

Morphometry and immunocytochemistry

The use of morphometry (and stereology), especially in conjunction with immunocytochemistry, in surgical and experimental pathology is reviewed. The combined use of morphometry and immunocytochemistry permits the study of secretory products and the distinction between cells that produce them, e.g., as in the pancreas. Several examples to illustrate the application of immunocytochemical techniques in morphometry are presented. For example, using this approach on the pancreas, it was shown that not only B cells, but also A and D cells, seem to undergo pathologic changes in a prediabetic organism. Since morphologic alterations may be distributional as well as quantitative, a model for the assessment and statistical evaluation of the distribution of objects within an area is discussed. Similar procedures were used to analyze the distribution of cytochrome P-450 molecules along intracellular membranes; however, special labeling techniques were necessary for this quantification in the electron microscope. Immunoenzyme cytochemically stained secretions can also be studied morphometrically, and microdensitometry and microfluorometry can also be used to quantify immunocytochemical reactions, as is shown in the analysis of the intralobular distribution of NADPH-cytochrome P-450 reductase in the rat liver. Finally, the BIVAS semiautomatic system for morphometric measurements, developed at the Department of Pathology of the University of Basel, is briefly described.     

PEROXISOMES IN ABSORPTIVE CELLS OF MAMMALIAN SMALL INTESTINE

Huge numbers of peroxisomes are present in guinea pig duodenum, jejunum, and ileum, and in rat duodenum. The peroxisomes have been studied by light and electron microscopy, including visualization by incubation in a newly-developed alkaline 3,3' diaminobenzidine (DAB) medium. Electron micrographs of more than 3700 guinea pig peroxisomes have been studied. The diameter of most peroxisomes ranges from 0.15 µ. to 0.25 µ. They often appear in clusters, surrounded by and continuous, in numerous places, with smooth endoplasmic reticulum (ER). The ER is extremely tortuous in these regions. Serial sectioning is valuable for studying the ER-peroxisome relationships but viewing sections at different angles, tilted with a goniometer stage, is more informative. The intimate relations of the two organelles appear the same in tissue fixed in four different fixatives. The peroxisomes may be interpreted as localized dilatations of smooth ER retaining multiple membranous continuities. This interpretation is discussed in light of the turnover data on peroxisomal proteins of rat hepatocytes reported by Poole and colleagues. The very large numbers of peroxisomes in intestinal epithelium lead to speculations concerning their functional significance. They resemble the small peroxisomes described in many other cell types. Although the distinctive relationship of these peroxisomes to the ER is probably more significant than their small size, for practical purposes we propose the term "microperoxisomes" to distinguish these peroxisomes from the better-known larger peroxisomes of liver and kidney.     

Light microscopic immunocytochemical demonstration of peroxisomal enzymes in epon sections

Summary A procedure is described for light microscopic immunocytochemical localization of catalase and three enzymes of peroxisomal lipid -oxidation: acyl-CoA oxidase, enoyl-CoA hydratase and 3-ketoacyl-CoA thiolase in semithin sections of rat liver processed for routine electron microscopy. Satisfactory immunostaining required the removal of the epoxy resin with sodium ethoxide, controlled digestion of deplasticized sections with proteases and, in case of osmiumfixed tissue, bleaching with oxidants. Resin removal was essential for successful immunostaining, and protease treatment enhanced markedly the intensity of the reaction. This study shows that tissues processed for conventional ultrastructural studies can be used for postembedding immunocytochemical demonstration of various peroxisomal enzymes.Supported by the Alexander-von-Humboldt Foundation